JP4180944B2 - Low floor vehicle - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a technique for improving an engine mounting structure of a low floor vehicle.
[0002]
[Prior art]
In a low-floor type vehicle such as a scooter type motorcycle / tricycle, a technique for mounting a front / rear V-type engine in a lower part of a body frame is known (for example, see Patent Documents 1 to 3).
[0003]
[Patent Document 1]
JP 2002-19678 A (page 3-5, FIGS. 1 and 7)
[Patent Document 2]
Japanese Patent Laid-Open No. 2001-87763 (page 3, FIG. 1-2)
[Patent Document 3]
Japanese Patent Laid-Open No. 10-167156 (page 3, FIG. 1-3)
[0004]
According to Patent Document 1, a conventional low-floor type vehicle {circle around (1)} is provided with a front fuel tank and a rear storage space under the seat, and the left and right low seats on which the driver sitting on the seat puts his / her foot in front of the seat. A floor is provided, and a straddle part (specifically, a center tunnel) with a height that allows the driver to straddle between these left and right low floors is provided, an engine is provided under the straddle part, and the engine is placed in front of the head pipe. An air cleaner was installed.
[0005]
According to Patent Document 2, the conventional low-floor type vehicle (2) is provided with a front fuel tank and a rear storage space under the seat, with left and right low floors in front of the seat, and between these left and right low floors. Is provided with a straddle that is high enough for the driver to straddle, a V-type engine is provided below the straddle, and an air cleaner is provided directly behind the head pipe.
[0006]
According to Patent Document 3, a conventional low-floor type vehicle (3) is provided with a transmission under the seat, with left and right low floors in front of the seat, and the driver straddles between the left and right low floors. A straddle part having a height that can be formed is provided, an engine is provided below the straddle part, and an air cleaner is provided directly behind the head pipe.
[0007]
[Problems to be solved by the invention]
However, the conventional low-floor type vehicle {circle around (1)} is arranged with the engine cylinder facing forward and in front of and below the straddle portion. The space in front of the engine must be narrowed by the amount of cylinder facing forward. For example, there is a limit to disposing an air cleaner in this narrow space. For this reason, an air cleaner is disposed in front of the head pipe. As a result, the intake connecting pipe connecting the air cleaner and the engine has to have a complicated shape. Therefore, there is room for improvement in order to improve engine performance.
The same applies to the conventional low floor type vehicles (2) and (3).
[0008]
Therefore, an object of the present invention is to provide a technique capable of improving the performance of an engine mounted on a low floor type vehicle.
[0009]
[Means for Solving the Problems]
  In order to achieve the above object, claim 1 is a low-floor type vehicle such as a scooter type motorcycle or a tricycle, wherein a storage space is provided under the seat, and a driver sitting on the seat in front of the seat In the low-floor type vehicle where the left and right low floors on which the feet are placed are provided, and a straddle portion with a height that the driver can straddle between the left and right low floors is provided, and the engine is provided under the straddle portion,The low-floor type vehicle includes a diamond-shaped frame including a pair of left and right upper frames extending downward from the head pipe and a down frame extending downward from the head pipe. A V-type engineThe engine is a V-type engine having a front cylinder and a rear cylinder, and a crankshaft is disposed under the straddle portion,RearThe cylinder axis is directed upward, and the top of the cylinder faces the straddle,A fuel tank is provided in front of the straddle, above the air cleaner connected to the engine and above the upper frame.It is characterized by that.
[0010]
  In claim 1,In low-floor vehicles such as scooter type motorcycles and tricycles, the engine crankshaft is placed under the straddle and the engineRearSince the top of the cylinder faces the straddle, a large space can be secured in front of the engine.
  By effectively utilizing this space and arranging the intake system including the intake connection pipe and the air cleaner, the intake connection pipe can have a relatively simple shape close to a straight line. Therefore, the intake system and the V-type engine can be efficiently connected, and the performance of the engine can be improved. Furthermore, the degree of freedom in designing the intake system is increased.
  Furthermore, by disposing the air cleaner at a relatively low position in front of the engine, it is possible to secure a relatively low additional space above the air cleaner. By effectively utilizing this additional space, functional parts such as a fuel tank can be easily arranged.
  Further, since the two cylinders of the V-type engine are arranged in the front-rear direction, the vehicle width does not have to be widened, and the running performance can be improved.
[0011]
  In claim 1,A fuel tank in front of the straddle,, EnAbove the air cleaner connected to the gin, andA pair of left and right sides extending downward from the head pipeProvided above the upper frameSoBy placing a fuel tank in front of the straddle, it is not necessary to place a fuel tank below the seat, so a large space is secured under the seat and the storage capacity of the storage box is greatly increased (increasing capacity) And the degree of freedom in designing the storage box can be increased.
  In addition, the air cleaner is disposed at a relatively low position, and the fuel tank can be easily disposed in a space secured above the air cleaner, so that the space can be effectively used.
[0012]
  Furthermore, in claim 1,The low-floor type vehicle includes a diamond-shaped frame including a pair of left and right upper frames extending rearward and downward from the head pipe and a down frame extending rearward and downward from the head pipe. The diamond-type frame with the engine connected to the down frame because the type engine is suspended.AndThe engine can be easily lowered to the minimum ground level. Therefore, the center of gravity of the low floor vehicle can be easily lowered.
  Claim 2 is the method of claim 1,The bank angle of the V-type engine is set to 90 ° or an angle exceeding 90 °, and the bisector of this bank angle is set toThe head pipeIt is characterized by being directed to.
  In claim 2,By setting the bank angle to 90 ° or an angle exceeding 90 °, a large space is provided between the V banks, and an intake system including an intake connecting pipe and an air cleaner is disposed in the space. Can be efficiently connected, and engine performance can be improved.
  Claim 3 is the method of claim 1,The bottom surface of the substantially planar air cleaner to which the intake connection pipe is connected is substantially orthogonal to the bisector of the bank angle, and the upper frame and the down frame are substantially straight from the bottom surface of the air cleaner to the vicinity of each cylinder. It is made to form in.
  In claim 3,Since the space inside the body frame can be effectively used and arranged compactly, the degree of freedom in design can be increased, and the appearance of the low-floor type vehicle can be improved. Furthermore, the ease of straddling the body frame can be improved when the driver gets on.
  Claim 4 is the method of claim 1,SaidRearThe cylinder is arranged between the left and right upper frames, and the tip of the rear cylinder is substantially coincident with the contour line on the upper side of the upper frame.
In claim 4, the rearSince the cylinder is disposed between the left and right upper frames, even if the upper frame is lowered, it does not interfere with the cylinders in the rear bank.
  For this reason, it is possible to pass the upper frame as low as possible. Accordingly, the center of gravity of the vehicle body frame is lowered, so that the center of gravity of the low floor type vehicle can be lowered. In addition, since the low floor can be made lower, the comfortability and footing of the low floor vehicle are improved. Furthermore, lowering the upper frame makes it easier to straddle the body frame when the driver gets on.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the accompanying drawings. “Front”, “Rear”, “Left”, “Right”, “Up”, “Down” follow the direction seen from the driver, Fr is front, Rr is rear, L is left, R is right CL indicates the vehicle width center (vehicle body center). The drawings are viewed in the direction of the reference numerals.
[0014]
First, the overall configuration of the low floor vehicle 10 will be described. FIG. 1 is a left side view (part 1) of a low floor type vehicle according to the present invention, and shows a configuration in which a vehicle body cover is mounted. FIG. 2 is a left side view (part 2) of the low floor type vehicle according to the present invention, and shows a configuration in which the vehicle body cover is removed. FIG. 3 is a plan view of a low-floor type vehicle according to the present invention, showing a configuration in which a vehicle body cover is removed.
[0015]
The low floor type vehicle 10 includes a body frame 20, a front fork 51 attached to the head pipe 21 of the body frame 20, a front wheel 52 attached to the front fork 51, a handle 53 connected to the front fork 51, and the body frame 20. A power unit 54 attached to the lower part of the vehicle body, a radiator 55, an air cleaner 56 and a fuel tank 57 attached to the front upper part of the vehicle body frame 20, a seat 58 attached to the rear upper part of the vehicle body frame 20, and the vehicle body frame 20 below the seat 58. A storage box 59 attached to the rear part, a swing arm 62 suspended by a rear wheel rear cushion 61 on the rear part of the body frame 20, and a rear wheel 63 attached to the swing arm 62 are main components, and the entire vehicle body Full cowling type vehicle with body cover (cowl) 70 covered A.
[0016]
More specifically, the seat 58 is a tandem seat for two passengers in the front and rear, and is provided with a movable (adjustable) seat back 64 for the driver in the center. Such a seat 58 can be attached to the vehicle body frame 20 by a seat rail 65 extending rearward from the rear upper part of the vehicle body frame 20.
P1 is an intermediate position of the wheel base (the distance between the centers of the front wheel 52 and the rear wheel 63), and the distance X1 and the distance X2 are equal.
[0017]
As shown in FIG. 1, the vehicle body cover 70 includes a front cover 71 that covers the front part of the head pipe 21 and the upper part of the front wheel 52, an inner cover 72 that covers the rear part of the front cover 71, and a step of placing the driver's feet. Left and right low floors 73 as the floor (only the left side is shown), the left and right floor skirts 74 extending downward from the outer edges of the low floor 73, and the longitudinal center of the body frame 20 extending rearward from the inner cover 72 A center cover 75 that covers the vehicle body, a side cover 76 that extends rearward from the center cover 75 and covers the rear part of the vehicle body frame 20, the seat rail 65, and the storage box 59, and a rear cover 77 that covers the rear upper part of the vehicle body behind the side cover 76. Become.
[0018]
FIG. 2 shows that the front cover 71 and the engine radiator 55 covering the front part of the vehicle body frame 20 are supported by the vehicle body frame 20 via the stay 320.
[0019]
The center cover 75 is a member that also covers the air cleaner 56, the fuel tank 57, and the engine 100.
In the figure, 81 is a wind screen, 82 is a front fender, 83 is a headlamp, 84 is a winker, 85 is a rear spoiler and rear grip, 86 is a tail lamp, 87 is a rear fender, and 88 is a number plate.
[0020]
Next, the body frame 20 will be described. 4 is a left side view of the vehicle body frame according to the present invention, FIG. 5 is a plan view of the vehicle body frame according to the present invention, FIG. 6 is a front view of the vehicle body frame according to the present invention, and FIG. FIG. 8 is a perspective view of the vehicle body frame according to the present invention as seen from the right side.
[0021]
The body frame 20 includes a pair of left and right upper frames 22 and 22 extending rearward and downward from the head pipe 21, and a front portion of a crankcase 104 of the V-type engine 100 (see FIG. 2) extending downward from the head pipe 21. And a pair of left and right down frames 23, 23 connected to each other, and a diamond type frame on which the V-type engine 100 is suspended.
[0022]
More specifically, the upper frames 22 and 22 extend in a substantially straight line while inclining from the upper part of the head pipe 21 to the rear and lower part, and the pipe material extending from the lower inclined end part 22a to the rear and lower part with a gentle inclination. It is. The down frames 23, 23 are pipe members that extend from the lower part of the head pipe 21 to the rear lower side with a larger inclination angle than the upper frames 22, 22.
[0023]
Between the left upper frame 22 and the left down frame 23 and between the right upper frame 22 and the right down frame 23 is a truss-shaped frame structure (triangular frame structure).
[0024]
Specifically, in the truss-shaped frame structure, a substantially horizontal first reinforcing member 24 extends from the joint portion of the head pipe 21 and the down frame 23 toward the upper frame 22, and the upper frame 22 and the first reinforcing member 24 are extended. The second reinforcing member 25 is extended from the joining portion to the lower end portion of the down frame 23 and joined, and further, between the vicinity of the downward inclined end portion 22a of the upper frame 22 and the second reinforcing member 25 being extended. By having a configuration in which the third reinforcing material 26 is stretched over the three space portions 27 to 29 having a triangular shape in a side view. These space portions 27 to 29 penetrate in the vehicle width direction.
[0025]
That is, the first space portion 27 is a space formed by the head pipe 21, the upper frame 22, and the first reinforcing member 24. The second space 28 is a space formed by the down frame 23 and the first and second reinforcing members 24 and 25. The third space 29 is a space formed by the upper frame 22 and the second and third reinforcing members 25 and 26.
[0026]
Further, the vehicle body frame 20 has a cross member 31 placed between the left and right upper frames 22 and 22 in the vicinity of the downwardly inclined end portion 22a of the upper frame 22, while the left and right down frames 23 and 23 are being extended. Rigidity is ensured by spanning two cross members 32 and 33 between them. The cross member 31 between the left and right upper frames 22 and 22 includes a cushion bracket 34.
[0027]
The body frame 20 includes a left first hanger plate 35 at the lower end of the left down frame 23, a left second hanger plate 36 at the left third reinforcing member 26, and the left upper frame 22 and the left third hanger plate 36. A left third hanger plate 37 is provided in the vicinity of the joint portion with the reinforcing member 26, a left fourth hanger plate 44 is provided at the rear end portion of the left upper frame 22, and a right down frame 23 is provided as shown in FIG. The right hanger 23a is provided at the lower end of the right side, the right third hanger 26 is provided with the right first hanger plate 38, and the right second hanger 23 is provided in the vicinity of the joint between the right upper frame 22 and the right third reinforcing member 26. A hanger plate 39 is provided, and a right third hanger plate 48 is provided at the rear end of the right upper frame 22.
These hanger plates 35 to 39, 44, 48 are connecting members that can be removed from the vehicle body frame 20.
[0028]
Further, as shown in FIGS. 5 and 8, the vehicle body frame 20 has left and right low floor support frames 41, 42 fixed to the lower portions of the down frames 23, 23 via stays 47, 47. These left and right low floor support frames 41 and 42 are members that extend in the front-rear direction and support the low floor 73 (see FIG. 1).
The left low-floor support frame 41 is a pipe member whose rear portion is connected to the rear portion of the left upper frame 22 by a stay 43 and a left fourth hanger plate 44, and a side stand 46 is integrally held at the rear portion. is there. The left fourth hanger plate 44 also serves as a stay for the low floor support frame.
[0029]
Specifically, a side stand 46 is attached to the left low floor support frame 41 by a bracket 45 so that the side stand 46 can be stood and stowed. As shown in FIG. 8, the lower floor support frame 42 on the right is connected to a bracket 172 of the transmission unit 130 whose rear portion is indicated by an imaginary line.
[0030]
The mounting structure of the low floor support frames 41 and 42 will be described collectively.
Low floor support frames 41 and 42 extending in the front-rear direction are fixed to lower portions of the down frames 23 and 23 of the diamond type frame, and the low floor 73 (see FIG. 1) is supported by the low floor support frames 41 and 42. I did it. For this reason, it can comprise so that the V-type engine 100 (refer FIG. 2) may be lowered | hung, and the low floor 73 can be supported reliably.
[0031]
Furthermore, the rear part of the left low-floor support frame 41 fixed to the lower part of the left down frame 23 was also connected to the rear part of the left upper frame 22 (see FIGS. 2 and 7). For this reason, the left low-floor support frame 41 that is long in the front-rear direction can be sufficiently fixed by the vehicle body frame 20. As a result, the rigidity of the low floor support frame 41 can be increased, the low floor 73 can be more reliably supported, and the support rigidity can be further increased.
[0032]
On the other hand, as shown in FIG. 8, the rear portion of the right low floor support frame 42 fixed to the lower portion of the right down frame 23 is further connected to the transmission unit 130 having higher rigidity. Therefore, the right low floor support frame 42 that is long in the front-rear direction can be sufficiently fixed by the vehicle body frame 20 and the transmission unit 130. As a result, the rigidity of the low floor support frame 42 can be increased, the low floor 73 can be more reliably supported, and the support rigidity can be further increased.
[0033]
Furthermore, as shown in FIG. 4, since the side stand 46 is integrally held at the rear portion of the left low floor support frame 41, the low floor support frame 41 can also serve to hold the side stand 46. For this reason, sharing with other functional parts can be achieved, the bracket 45 for holding the side stand 46 can be small, and there is no need to provide a holding part consisting of separate parts. In addition, since the side stand 46 is held by the low floor support frame 41 extending in the front-rear direction, the side stand 46 can be set at an arbitrary position in the front-rear direction, and the degree of freedom in design is increased.
[0034]
Next, the configuration around the power unit 54 will be described. FIG. 9 is a left side view around the vehicle body frame, power unit, air cleaner, and fuel tank according to the present invention.
The power unit 54 is a combination of the front and rear V-type engine 100 and the rear transmission unit 130. That is, the transmission unit 130 is provided in the power unit 54.
[0035]
  As shown in FIG. 9, the V-type engine 100 is a two-cylinder engine in which the bank angle θ <b> 1 (the sandwich angle θ <b> 1 between the cylinders 101 and 102) is set to approximately 90 ° or an angle exceeding 90 ° in a side view. In V-type engine 100, front bank cylinder 101, that is, front cylinder 101(Its axis)The wheel extends substantially horizontally forward so as to be directed above the axle of the front wheel 52 (see FIG. 2). Cylinder 102 in the rear bank, that is, rear cylinder 102(Its axis)Extends upwards generally vertically so as to be directed to the lower inclined end portion 22a of the upper frame 22. The present invention is characterized in that the V-type engine 100 is arranged such that the bisector L1 of the bank angle θ1 is directed to the head pipe 21.
[0036]
Further, FIG. 9 shows that the crankshaft 103 of the V-type engine 100 is disposed in front of the wheel base intermediate position P1 (see FIG. 2), so that the cylinder 101 in the front bank is positioned more than the left and right down frames 23, 23. This shows that the cylinders 102 in the front bank and the cylinders 102 in the rear bank are arranged between the left and right upper frames 22 and 22 (see also FIG. 3).
[0037]
By disposing the cylinder 101 in the front bank in front of the left and right down frames 23, 23, the V-type engine 100 can be disposed as far forward as possible. As a result, the center of gravity of the low floor type vehicle 10 can be set in front, so that the load applied to the front wheels 52 and the rear wheels 63 (see FIG. 2) can be more appropriately distributed.
[0038]
Furthermore, by disposing the cylinder 101 in the front bank in front, the position of the crankshaft 103 of the V-type engine 100 moves forward. Even in this case, the bisector L1 of the bank angle θ1 is directed to the head pipe 21. Since the bisector L1 of the bank angle θ1 rises as the position of the crankshaft 103 moves forward, the cylinder 102 in the rear bank tilts rearward in response to this. Therefore, the height of the cylinder 102 in the rear bank can be lowered. For this reason, the degree of freedom for mounting the V-type engine 100 is further increased.
[0039]
Furthermore, since the rear bank cylinders 102 are disposed between the left and right upper frames 22 and 22, even if the upper frames 22 and 22 are lowered, they do not interfere with the rear bank cylinders 102. For this reason, the upper frames 22 and 22 can be passed to a position as low as possible. Therefore, since the center of gravity of the body frame 20 is lowered, the center of gravity of the low floor type vehicle 10 can be lowered. And since the low floor 73 (refer FIG. 1) can be made lower, the comfortability and footing property of the low floor type vehicle 10 improve. Furthermore, lowering the upper frames 22 and 22 makes it easier to straddle the vehicle body frame 20 when the driver gets on.
[0040]
In order to allow the V-type engine 100 to be disposed in the front, a radiator 55 for the engine (water-cooled engine) 100 is disposed in front of the head pipe 21 as shown in FIG. Conventionally, the V-type engine 100 can be arranged as far forward as possible by moving the radiator 55 arranged in front of the water-cooled engine to the front of the head pipe 21.
[0041]
The V-type engine 100 and the transmission unit 130 are arranged with their lower half portions lowered below the low floor support frames 41 and 42 (shown only on the left in this figure). For this reason, the V-type engine 100 and the transmission unit 130 may be disposed below the low floor 73 (see FIG. 1) supported from below by the low floor support frames 41 and 42 and mounted on the low floor vehicle 10. it can. The crankshaft 103 is located below the low floor 73 and the low floor support frames 41 and 42.
[0042]
By doing so, the V-type engine 100 and the intake system 190 are arranged in the space S1 below the straight line L2 passing through the center point P2 of the head pipe 21 and the final output shaft 138 of the transmission unit 130. . In addition, the bisector L1 of the bank angle θ1 can be directed to the head pipe 21.
[0043]
Here, the intake system 190 is a system for supplying combustion air to the V-type engine 100 and includes an air cleaner 56 and intake connection pipes 191 and 191 connected from the air cleaner 56 to the cylinders 101 and 102.
[0044]
Since the bisector L1 of the bank angle θ1 is directed to the head pipe 21 and the V-type engine 100 is arranged, the bisector L1 is oriented in the direction in which the vehicle body rigidity is strong. On the other hand, the intake pipe including the intake pipes 191 and 191 and the air cleaner 56 for the respective cylinders 101 and 102 can be used more effectively and the space between the head pipe 21 and the two cylinders can be used effectively. A large space for arranging the system 190 can be secured. Therefore, the degree of freedom in designing the intake system 190 is increased.
[0045]
Further, since the intake system 190 including the intake coupling pipes 191 and 191 and the air cleaner 56 is disposed in such a large space between the V banks so as to be directed to the head pipe 21, the intake system 190 and the V-type engine 100 are made efficient. The connection can be made well, and the performance of the V-type engine 100 can be improved. Further, the intake system 190 can be reduced in size and consolidated at a relatively low position. For this reason, the fuel tank 57 can be easily disposed on the upper portion of the low intake system 190 so that the mass can be concentrated on the front portion.
[0046]
By disposing the fuel tank 57 in the front part of the low floor type vehicle 10, the center of gravity of the low floor type vehicle 10 can be set forward, so that the load applied to the front wheel 52 and the rear wheel 63 can be more appropriately set. Can be allocated. Moreover, since it is not necessary to dispose the fuel tank 57 below the seat 58 (see FIG. 2), a large space is secured under the seat 58, and a storage box 59 (see FIG. 2) having a large storage space is disposed. , Exert a great effect.
[0047]
  Furthermore, since the V-type engine 100 and the intake system 190 are arranged in the space S1 below the straight line L2 passing through the head pipe 21 and the final output shaft 138 of the transmission unit 130, the space S2 above the air cleaner 56 is effectively used. Can be used. Therefore, the fuel tank 57 as a functional component can be easily disposed above the air cleaner 56.
  The fuel tank 57 is disposed above the upper frames 22 and 22 as shown in FIGS.
[0048]
In the embodiment of FIG. 9, although the tip of the cylinder 102 in the rear bank and the upper end of the air cleaner 56 of the intake system 190 protrude slightly upward from the straight line L2, the upper contour lines of the upper frames 22 and 22 are projected. Can be regarded as being substantially disposed in the space S1 below the straight line L2 passing through the head pipe 21 and the final output shaft 138.
[0049]
Here, the relationship among the seat 58, the low floors 73 and 73, the center cover 75, and the engine 100 will be described together based on FIGS. 1 to 3 and FIG.
The center cover 75 in the vehicle body cover 70 is integrally provided with a straddle 78 having a height that allows the driver to stride between the left and right low floors 73 and 73 when riding. The straddling portion 78 covers the longitudinal center of the vehicle body frame 20, that is, around the lower inclined end portion 22 a (see FIG. 9) of the upper frame 22 and around the rear cylinder 102 of the V-type engine 100. It is a U-shaped cover.
[0050]
As shown in FIGS. 1 and 2, the low floor vehicle 10 has a storage space under the seat 58 (that is, a storage box 59), and a driver sitting on the seat 58 in front of the seat 58 Left and right low floors 73, 73 are provided, a straddle portion 78 is provided between the left and right low floors 73, 73, the engine 100 is provided under the straddle portion 78, and the fuel tank 57 is disposed in front of the straddle portion 78. Arranged scooter.
[0051]
The crankshaft 103 of the engine 100 is disposed below the straddling portion 78, that is, below the low floors 73 and 73, and the top of the cylinder of the engine 100 (rear cylinder 102) faces the straddling portion 78. As a result, a large space in front of the engine 100 can be secured. By effectively using this space and arranging the intake system pipes 191 and 191 and the air intake system 190 including the air cleaner 56, the intake connection pipes 191 and 191 can be formed in a relatively simple shape close to a straight line. Therefore, the intake system 190 and the V-type engine 100 can be efficiently connected, and the performance of the engine 100 can be improved. Furthermore, the degree of freedom in designing the intake system 190 increases.
[0052]
Furthermore, by disposing the air cleaner 56 at a relatively low position in front of the engine 100, a relatively low additional space can be secured above the air cleaner 56. By making effective use of this additional space, functional parts such as the fuel tank 57 can be easily arranged.
[0053]
Further, since the fuel tank 57 is disposed in front of the straddling portion 78, it is not necessary to dispose the fuel tank 58 below the seat 58, so that a large space is secured under the seat 58 and the storage capacity of the storage box 59 is secured. Can be greatly increased, and the degree of freedom in designing the storage box 59 can be increased.
[0054]
In addition, since the engine 100 is configured by a V-type engine including the front cylinder 101 and the rear cylinder 102, the space between the front and rear cylinders 101 and 102 can be used effectively. Therefore, a larger space can be secured in front of the engine 100. The intake system 190 can be arranged more easily by effectively using such a larger space.
Furthermore, by disposing the two cylinders 101 and 102 of the V-type engine 100 in the front-rear direction, the vehicle width is not increased, and the running performance is improved, and the vibration of the V-type engine 100 is more advantageous. be able to.
[0055]
FIG. 10 is a cross-sectional view of a power unit according to the present invention, and is expressed as a cross-sectional structure in which the power unit 54 is viewed from above. FIG. 11 is a cross-sectional view of the front half of the power unit according to the present invention. FIG. 12 is a cross-sectional view of the rear half of the power unit according to the present invention. FIG. 13 is a plan view of the rear portion of the power unit and the periphery of the swing arm for the rear wheel according to the present invention.
[0056]
10 to 12 show a cross-sectional configuration of the power unit 54. In the V-type engine 100, the cylinder 102 in the rear bank is omitted.
The V-type engine 100 includes a left and right split crankcase 104, a front bank cylinder 101 connected to the crankcase 104, a rear bank cylinder 102 (see FIG. 9), and a head connected to the tips of these cylinders 101, 102. 105, a head cover 106, a crankshaft 103 extending in the vehicle width direction and rotatably accommodated in the crankcase 104, a piston 108 connected to the crankshaft 103 by a connecting rod 107, and a valve operating valve accommodated in a cam chamber 109 A water-cooled engine including a mechanism 111, a spark plug 112, and the like and having a water-cooling jacket.
[0057]
In the figure, 113 is a cam chain, 114 is a cooling water pump drive gear, 115 is a right side cover, 116 is an AC generator, and 117 is a crankshaft drive gear by a starter motor (described later).
By covering the left side cover 118 on the left side portion of the crankcase 104, the left end portion of the crankshaft 103, the AC generator 116, and the left end portion of the first transmission shaft 136 described later are largely covered.
[0058]
The transmission unit 130 is coupled to the engine 100 at one side (right side R) of the V-type engine 100, extends rearward at one side (right side R) of the low floor type vehicle 10, and swings for the rear wheel. The rear wheel 63 is configured to be driven from the other side portion (left side L) of the low floor type vehicle 10 at the pivot portion of the arm 62.
In this manner, the power unit 54 is configured by combining the crankcase 104 and the transmission unit 130 in a substantially U shape in plan view, and the plan view in the plan view on the other side portion (left side L) of the low floor vehicle 10. A letter-shaped opening (a space S4 of the opening portion having a substantially U-shape in plan view) can be provided.
Since it comprised in this way, only the V-type engine 100 or the transmission unit 130 can be changed, and it becomes the power unit 54 with high versatility.
[0059]
More specifically, the transmission unit 130 includes a main case 131 that is attached to the rear right surface of the crankcase 104 and extends rearward, a first cover 132 that closes a right opening of the main case 131, and the main case 131 and the first cover 132. The first transmission chamber 133 formed, the sub case 134 superimposed on the left side of the rear portion of the main case 131, the second transmission chamber 135 formed by the main case 131 and the sub case 134, and the rear portion in the crankcase 104 A first transmission shaft 136 extending in the vehicle width direction into the first transmission chamber 133, a second transmission shaft 137 extending in the vehicle width direction from the rear portion in the first transmission chamber 133 into the second transmission chamber 135, and a second speed change A final output shaft 138 extending from the machine room 135 through the sub case 134 to the left and the left end of the first transmission shaft 136 from the left end of the crankshaft 103. The first gear mechanism 139 that transmits power, the belt type continuously variable transmission mechanism 141 that transmits power from the right end portion of the first transmission shaft 136 to the right end portion of the second transmission shaft 137, the centrifugal clutch 142, and the second transmission shaft 137 The second gear mechanism 143 transmits power from the left end to the final output shaft 138, and the like.
[0060]
The belt-type continuously variable transmission mechanism 141 employs a motor control system in which transmission control is performed via a transmission gear 147 by a servo motor (not shown).
144 is a balancer, 145 is a reluctator, and 146 is a pulsar (crankshaft angle sensor), which is used for ignition control and fuel injection control of the engine 100.
[0061]
Further, referring to FIG. 13, the transmission shaft 151 is splined to the left end of the final output shaft 138, the drive sprocket 152 is attached to the transmission shaft 151, and the driven sprocket 154 is attached to the axle 153 for the rear wheel 63. By applying a chain 155 between these drive / driven sprockets 152 and 154, the power of the V-type engine 100 can be transmitted from the transmission unit 130 to the rear wheel 63 by the chain drive mechanism 150.
[0062]
Incidentally, the axis C1 of the final output shaft 138 is also the pivot center C1 (swing center C1) of the rear wheel swing arm 62.
The swing arm 62 is a substantially H-shaped member in plan view, which includes a left arm 161, a right arm 162, and a cross member 163 that connects the left and right arms 161, 162. A rear wheel 63 is provided at the rear end of the swing arm 62. It can be supported rotatably.
[0063]
Such a swing arm 62 is arranged such that the rear right side surface of the main case 131 and the rear left side surface of the sub case 134 are sandwiched between the front ends of the left and right arms 161 and 162. The left supported portion 161a at the front end of the left arm 161 is supported by the left pivot 164 on the rear left side of the sub case 134, and the right supported portion 162a at the front end of the right arm 162 is supported at the rear portion of the main case 131. The swing arm 62 can be mounted so as to swing up and down by being supported on the right side by the right pivot 165.
[0064]
The pivot 165 is a male screw screwed into the main case 131 so as to be able to appear and retract. The main case 131 is pulled in advance by screwing the pivot 165, the swing arm 62 is aligned with the pivot center C1, and then the tip of the pivot 165 is exposed and fitted to the right supported portion 162a. The right supported portion 162 a can be attached to the case 131.
[0065]
The left arm 161 also serves as a chain case. By covering the left opening of the left arm 161 with a chain cover 166, the drive / driven sprockets 152 and 154 and the chain 155 can be accommodated.
[0066]
As is apparent from the above description, the power unit 54 includes the rear end portion of the crankcase 104, the left side portions of the main and sub cases 131 and 134 of the transmission unit 130, and the front end portion of the left arm 161 of the swing arm 62. Can be provided on the other side (left side L) of the low-floor vehicle 10.
[0067]
Next, the relationship between the body frame 20 and the power unit 54 will be described. FIG. 14 is a perspective view of the vehicle body frame and the power unit according to the present invention as viewed from the left front. FIG. 15 is a perspective view of the vehicle body frame, the power unit, and the air cleaner according to the present invention as viewed from the left rear. FIG. 16 is a perspective view of the vehicle body frame, the power unit, and the air cleaner according to the present invention as viewed from the right front.
FIG. 17 is a perspective view of the vehicle body frame and the power unit according to the present invention as viewed from the right rear.
[0068]
14 to 17 show that the V-type engine 100 and the transmission unit 130 are suspended on the vehicle body frame 20 which is a diamond-type frame.
For the V-type engine 100, the left side of the crankcase 104 is attached to the vehicle body frame 20 via the left, first, second, and third hanger plates 35, 36, and 37, and the right side of the crankcase 104 is It was attached to the vehicle body frame 20 via the hanger part 23a and the right first hanger plate 38.
[0069]
On the other hand, for the transmission unit 130, the upper portion of the left side portion of the main case 131 is attached to the vehicle body frame 20 via the left and right third and fourth hanger plates 37 and 44, and the upper portion of the right side portion of the main case 131 is It was attached to the vehicle body frame 20 via the second and third hanger plates 39 and 48 on the right side.
The cross members 32 and 33 also serve as engine guard members.
[0070]
Since the vehicle body frame 20 is a diamond-type frame and the V-type engine 100 is suspended from the diamond-type frame, the engine 100 can be a part of the vehicle body frame 20. For this reason, it is not necessary to pass the frame member under the V-type engine 100. Therefore, the V-type engine 100 can be lowered to the minimum ground height. As a result, as shown in FIG. 9, the crankshaft 103 of the V-type engine 100 is also lowered, so that the space above the low floor 73 (see FIG. 1) can be widened accordingly. Furthermore, by lowering the V-type engine 100, the low floor 73 can be disposed above the crankcase 104, and the step width (the width of the low floor 73) can be reduced.
[0071]
As described above, according to the layout of the present invention, the degree of freedom of mounting the V-type engine 100 having the bank angle θ1 of approximately 90 ° or greater than 90 ° can be further increased. In addition, the center of gravity of the low floor vehicle 10 can be lowered by lowering the V-type engine 100.
[0072]
Referring to FIG. 9, the upper frames 22, 22 extend substantially linearly while inclining rearward and downward to the vicinity of the cylinder 102 of the rear bank of the V-type engine 100, and then the degree of inclination is made moderate to make the rear The wheel swing arm 62 extends to the vicinity of the pivot (position of the final output shaft 138).
[0073]
In this way, the upper frames 22 and 22 can be extended substantially linearly in the front-rear direction. For this reason, the rigidity of the upper frames 22 and 22 can be further increased, and as a result, the rigidity of the vehicle body frame 20 can be further increased.
As described above, the front portions of the upper frames 22 and 22 contribute to the stability of the intake system 190, and the rear portions of the upper frames 22 and 22 can function to effectively receive the load from the rear wheel 63. Therefore, the rigidity of the vehicle body frame 20 can be effectively maintained by a small and lightweight configuration.
[0074]
As shown in FIG. 15, the left and right first reinforcing members 24, 24 in the body frame 20 are formed to be curved outward, whereby the capacity of the air cleaner 56 can be increased and the air cleaner 56 is disposed forward. Even so, it is possible to prevent interference with the head pipe 21 or interference within the maximum turning range of the front fork 51 (see FIG. 2).
[0075]
In FIG. 15, reference numeral 148 denotes a continuously variable transmission ratio variable servo motor which controls the continuously variable transmission ratio of the belt type continuously variable transmission mechanism 141 via the transmission gear 147 shown in FIG. In FIG. 16, reference numeral 121 denotes an engine cooling water pump (cooling water pump) 121. Further, FIGS. 16 and 17 show that the transmission unit 130 is attached to the right side surface of the crankcase 104 with bolts so as to be detachable at the bracket 172 at the upper right part and an attaching portion in the unit (not shown).
[0076]
By the way, as shown in FIG. 9, the crankcase 104 and the transmission unit 130 are connected to each other by the left third hanger plate 37 and the connecting member 173, and the left third hanger plate 37 and the connection. This shows that the member 173 is provided on the opening side of the power unit 54 that is substantially U-shaped in plan view. The left third hanger plate 37 serves as a connecting member.
[0077]
Specifically, the front portion of the connecting member 173 is attached to the lower left rear portion of the crankcase 104 with two bolts 174 and 174, and the rear portion of the connecting member 173 is attached to the lower left front portion of the transmission unit 130 with one bolt 175. It was.
A front portion of the left third hanger plate 37 (connection member 37) is attached to the left rear upper portion of the crankcase 104 with a single bolt 178, and a rear portion of the left third hanger plate 37 is mounted on the left front upper portion of the transmission unit 130. Was attached with one bolt 179.
[0078]
By doing in this way, sufficient rigidity of power unit 54 can be secured. Accordingly, the rigidity of the power unit 54 including the engine 100 and the transmission unit 130 that are part of the body frame 20 is increased, and thus the rigidity of the body frame 20 can be further increased.
[0079]
Furthermore, by providing the upper and lower connecting members 37 and 173 on the substantially U-shaped opening side of the power unit 54 in plan view, the opening portion can be reinforced by the upper and lower connecting members 37 and 173, so that it is efficiently desired. The rigidity of the low-floor type vehicle 10 is enhanced because the connecting members 37 and 173 do not protrude from the vehicle body.
[0080]
Further, the connecting member 173 is configured to hold a main stand (stand member) 176 as shown in FIGS. That is, by connecting the upper left part of the main stand 176 that is substantially gate-shaped in front view to the lower end part of the connecting member 173 and connecting the upper right part of the main stand 176 to the lower part of the transmission unit 130 via the stay 177, A main stand 176 was attached to be able to stand up and retract.
[0081]
Since the connecting member 173 for securing the rigidity of the power unit 54 also serves to hold the main stand 176, it is possible to achieve common use with other functional parts. A small, lightweight and small configuration can be achieved.
[0082]
Next, the intake system 190 will be described. FIG. 18 is a left side view around the body frame, the V-type engine, and the intake system according to the present invention, in which the air cleaner 56 is shown in cross section. FIG. 19 is a rear sectional view around the air cleaner and the vehicle body cover according to the present invention, FIG. 20 is an exploded view of the air cleaner according to the present invention, and FIG. 21 is an operation diagram of the air cleaner according to the present invention.
[0083]
9 and FIG. 18, an intake system 190 including intake coupling pipes 191 and 191 and an air cleaner 56 is disposed above the V-type engine 100, and an upper part of the air cleaner 56 is a vehicle accessory. It is shown that a space S2 for arranging the fuel tank 57 is provided.
More specifically, an intake system 190 is disposed between the V banks of the V-type engine 100 (between the cylinders 101 and 102) so as to be directed toward the head pipe 21, and a fuel tank 57 is disposed above the intake system 190.
[0084]
More specifically, the V-type engine 100 includes intake connection pipes 191 and 191 that connect the cylinders 101 and 102 to the air cleaner 56, respectively. The intake connecting pipes 191 and 191 include throttle valves 192 and 192 and fuel injection valves 193 and 193, respectively, and air supply pipes (funnels) 194 and 194 extending into the air cleaner 56, respectively. The air supply pipes 194 and 194 are connected to respective one ends of the intake coupling pipes 191 and 191 and arranged in a substantially C shape in a side view. A filter element 206 is disposed between the air pipes 194 and 194.
[0085]
In the figure, 149 is a cell motor. Reference numeral 195 denotes an intake air temperature sensor that detects the intake air temperature in the air cleaner 56, and is used to correct the intake amount of the fuel injection valves 193 and 193 with the intake air temperature.
[0086]
As shown in FIGS. 18 to 20, the air cleaner 56 can be maintained and inspected from the side of the low floor vehicle 10. A specific configuration of the air cleaner 56 includes a cleaner case 201, a removable bottom plate 203 that closes the lower end opening 202 of the cleaner case 201, two air supply pipes 194 and 194 that extend from the bottom plate 203 into the case, and the cleaner case 201. Removable inspection lid 205 for closing the inspection opening 204 provided in the rear upper part, a cylindrical filter element 206 housed in the cleaner case 201, and a filter inspection provided on the left side or right side of the cleaner case 201 It comprises a hole 207, a removable cover member 208 that closes the filter inspection hole 207, and a substantially L-shaped intake pipe 209 provided in the cover member 208.
The cleaner case 201 closed by the bottom plate 203 has a function of an engine intake chamber.
[0087]
The lid member 208 is attached to one end of the intake pipe 209 so as to be detachable, includes a communication pipe 211 that communicates with the intake pipe 209, and is attached to one end of the filter element 206 that communicates with the communication pipe 211 so as to be detachable. In this way, the air cleaner 56 includes the filter element 206 inside, and can be configured to be removable by the lid member 208 on the side of the air cleaner 56.
[0088]
The center cover 75 (a part of the vehicle body cover 70) covering the air cleaner 56 is provided with an inspection hole 75a and a removable inspection lid 212 that closes the inspection hole 75a. The inspection lid 212 is at a position facing the lid member 208.
[0089]
The air taken in from the intake pipe 209 passes through the communication pipe 211, the filter element 206, the cleaner case 201, the air supply pipes 194 and 194, and the intake connection pipes 191 and 191, and then each cylinder 101 of the V-type engine 100 shown in FIG. , 102.
[0090]
In order to maintain and inspect the filter element 206, as shown in FIG. 21, first, the screw 213 is removed and the locking groove 212a at one end of the inspection lid 212 is pulled out from the edge of the inspection hole 75a. Thus, the inspection lid 212 is detached from the center cover 75.
Next, the screw 214 is removed and the lid member 208 is removed through the inspection hole 75a. As a result, the intake pipe 209 and the filter element 206 are also removed together with the lid member 208.
In order to return the filter element 206 to its original state, the reverse procedure to the above-described removal procedure may be performed.
[0091]
As is clear from the above description, since the air cleaner 56 is configured to be maintained and inspected from the side of the low floor type vehicle 10, it is not necessary to perform maintenance and inspection from the upper part of the air cleaner 56. For this reason, a sufficiently large space that can be effectively used can be secured in the upper portion of the air cleaner 56.
[0092]
Further, the filter element 206 provided inside the air cleaner 56 is configured to be detachable by a lid member 208 on the side of the air cleaner 56, and the inspection lid 212 facing the lid member 208 is mounted on the vehicle body that covers the air cleaner 56. Since the cover 70 is provided, the filter element 206 can be easily detached from the side of the air cleaner 56 by removing the lid member 208 after removing the inspection lid 212. For this reason, the maintenance and inspection work of the filter element 206 is easy, and workability is enhanced.
[0093]
Furthermore, as shown in FIG. 18, since the filter element 206 is disposed between the plurality of air supply pipes 194, 194 extending into the air cleaner 56, when the filter element 206 is removed from the side of the air cleaner 56, the filter The element 206 does not interfere with the air pipes 194 and 194. For this reason, it is not necessary to enlarge the air cleaner 56 in order to prevent interference. Therefore, the air cleaner 56 can be reduced in size, and as a result, the degree of freedom in designing the air cleaner 56 to be mounted on the low floor vehicle 10 is increased.
[0094]
Further, by providing a space S2 in which the vehicle accessories such as the fuel tank 57 (see FIG. 9) are arranged at the upper portion of the air cleaner, the vehicle accessories can be easily arranged by effectively using the space S2. In addition, the degree of freedom in designing the load distribution can be increased. For example, since the center of gravity of the low floor type vehicle 10 can be set forward by disposing the air cleaner 56 and the fuel tank 57 at the front portion of the low floor type vehicle 10, the load applied to the front wheel 52 and the rear wheel 63. Can be distributed more appropriately.
[0095]
By the way, as shown in FIG. 18, each of the intake connecting pipes 191 and 191 is characterized by being disposed substantially along the upper frame 22 and the down frame 23. That is, the intake coupling pipe 191 connected to the cylinder 101 of the front bank is arranged substantially along the down frame 23, and the intake coupling pipe 191 connected to the cylinder 102 of the rear bank is arranged almost along the upper frame 22. Arranged.
[0096]
Therefore, the intake connecting pipes 191 and 191 can be configured in a substantially linear shape. By adopting the substantially straight intake connection pipes 191 and 191, air can be supplied more smoothly from the intake connection pipes 191 and 191 to the cylinders 101 and 102. As a result, the intake efficiency can be further improved, and the output performance of the V-type engine 100 can be further increased.
[0097]
In addition, by adopting such a configuration, the space inside the vehicle body frame 20 can be used effectively and compactly arranged, so that the degree of design freedom can be increased and the appearance of the low-floor vehicle 10 can be increased. Can also be increased. Furthermore, the ease of straddling the vehicle body frame 20 can be improved when the driver gets on.
[0098]
As described above, a truss-shaped frame structure is formed between the upper frame 22 and the down frame 23 facing the side surfaces of the intake coupling pipes 191 and 191. For this reason, it is possible to further increase the rigidity in the extending direction of the intake connecting pipes 191 and 191 in the vehicle body frame 20.
Accordingly, the rigidity of the vehicle body frame 20 itself can be ensured, and the vehicle parts such as the intake pipe in the vehicle body frame 20 can be firmly held, and these vehicle parts can be guarded by the vehicle body frame 20. Can have a role to play.
[0099]
The triangular second space 28 in the truss-shaped frame structure is a space in which the filter element 206 of the air cleaner 56 can be taken in and out. Since the second space portion 28 is provided, the filter element 206 can be easily detached from the side of the air cleaner 56. For this reason, the maintenance and inspection work of the filter element 206 is easy, and workability is enhanced. In addition, the air cleaner 56 can be reduced in size and weight.
[0100]
In FIG. 19, reference numerals 221 and 222 denote element pressing portions. In FIG. 20, reference numerals 223 and 223 denote air pipe connection joints, 224 and 224 denote air pipe connection flanges, 225... Screws, and 226 and 227 denote packings.
[0101]
Next, the exhaust system 240 of the V-type engine 100 will be described. 22 is a left side view around the vehicle body frame, power unit, and exhaust system according to the present invention, and FIG. 23 is a plan view around the vehicle body frame, power unit, and exhaust system according to the present invention.
[0102]
14 to FIG. 17, the exhaust system 240 of the V-type engine 100 includes a first exhaust pipe 241 connected to the cylinder 102 in the rear bank and a second exhaust pipe 241 connected to the cylinder 101 in the front bank. The exhaust pipe 242, the collecting pipe 243 that collects the rear end of the first exhaust pipe 241 and the rear end of the second exhaust pipe 242, and the silencer 245 connected to the rear end of the collecting pipe 243 via an extension pipe 244. It consists of. The silencer 245 incorporates a catalyst 246 (see FIG. 22) and is disposed on the upper right side of the rear wheel 63.
[0103]
The first exhaust pipe 241 connected to the cylinder 102 in the rear bank extends rearward (specifically, left rear) from the cylinder 102 in the rear bank, and the rear end extends downward. A space S4 having a substantially U-shaped opening is passed, its lower end is extended rearward (specifically, right rear) and passed under the power unit 54, and its rear end is passed through the collecting pipe 243 to the second exhaust pipe 242. Is connected to.
[0104]
Since the first exhaust pipe 241 connected to the cylinder of the rear bank 102 of the V-type engine 100 is passed through the space S4 of the substantially U-shaped opening portion of the power unit 54 in plan view, the space of the U-shaped opening portion S4 can be used effectively. For this reason, since the 1st exhaust pipe 241 does not protrude from a vehicle body, the external appearance property of the low floor type vehicle 10 improves.
[0105]
The second exhaust pipe 242 connected to the cylinder 101 of the front bank extends downward from the cylinder 101 of the front bank, extends its lower end to the right, extends its right end rearward along the lower right portion of the power unit 54, and then The end is connected to the collecting pipe 243.
[0106]
As shown in FIG. 14, the second exhaust pipe 242 passes through one side (right side) of the front surface of the V-type engine 100, and is placed on the crankcase 104 on the other side (left side) of the V-type engine 100. The oil filter 122 and / or the oil cooler 123 are provided. That is, an oil filter 122 and an oil cooler 123 are provided in the front part of the left half of the crankcase 104.
[0107]
As shown in FIG. 11, the transmission unit 130 is provided with an intake port 251 on the right side, and a fan 253 is provided on the pulley 252 of the belt type continuously variable transmission mechanism 141 to suck outside air into the transmission unit 130. It is the structure which air-cools. The exhausted air after cooling is released into the atmosphere by an exhausting member 254 provided at the rear upper part of the transmission unit 130 as shown in FIGS.
[0108]
The air exhaust member 254 is an upside down U-shaped duct in a side view, and is configured to apply exhaust air to the first and second exhaust pipes 241 and 242. The portion of the first and second exhaust pipes 241 and 242 where the exhaust air strikes is a gathered portion of the first exhaust pipe 241 and the second exhaust pipe 242, that is, the gather pipe 243 or the vicinity thereof. The exhaust sensor 255 is provided in a portion of the first and second exhaust pipes 241 and 242 where exhaust air strikes. That is, an exhaust sensor 255 is provided at the rear of the collecting pipe 243. The exhaust sensor 255 is cooled by the exhaust air, which is advantageous in maintaining the function and performance of the exhaust sensor 255.
[0109]
The exhaust sensor 255 detects the amount of oxygen in the exhaust gas. Based on this detection data, the injection amount of the fuel injection valves 193 and 193 (see FIG. 18) can be feedback controlled. For example, when the detected oxygen amount is large, it is assumed that the ratio of the fuel supply amount to the air supply amount is small, and the fuel injection valves 193 and 193 are controlled to increase the injection amount.
[0110]
As described above, since the exhaust sensor 255 is provided in the portion where the exhaust air hits the first and second exhaust pipes 241 and 242, the exhaust sensor 255 can be cooled by the exhaust air. Since the thermal effect of the exhaust sensor 255 due to the exhaust gas can be reduced, it is advantageous in maintaining the function and performance of the exhaust sensor 255. For example, the fuel injection valves 193 and 193 (see FIG. 18) can always be controlled to be properly controlled by the exhaust sensor 255.
[0111]
The exhaust system 240 will be described collectively.
Since the power unit 54 is configured in a substantially U shape in plan view, the first exhaust pipe 241 connected to the cylinder 102 in the rear bank of the V-type engine 100 extends rearward from the cylinder 102 and the rear end thereof extends downward. It extends through a space S4 having an opening that is substantially U-shaped in plan view, its lower end is extended rearward, and its rear end is connected to a second exhaust pipe 242 connected to the cylinder 101 of the front bank of the V-type engine 100. be able to.
[0112]
In this way, the first exhaust pipe 241 connected to the cylinder 102 of the rear bank passes over the power unit 54 and further extends downward through a space S4 having a substantially U-shaped opening in plan view. It can be used effectively and connected to the second exhaust pipe 242 connected to the cylinder 101 of the previous bank. Therefore, a plurality of exhaust pipes for the front and rear V-type engines can be efficiently arranged.
[0113]
Furthermore, since the exhaust of the exhaust member 254 provided at the rear portion of the transmission unit 130 is applied to the first and second exhaust pipes 241 and 242, the first and second exhausts are exhausted by exhaust. The pipes 241 and 242 and the exhaust gas in the pipe can be controlled to a desired temperature. In particular, both the first and second exhaust pipes 241 and 242 and the exhaust gas are cooled by the exhaust air after cooling the transmission unit 130, so that both can be cooled at the same time. There is no need to provide it, and the low floor type vehicle 10 can be downsized.
[0114]
Furthermore, since the exhaust air of the exhaust member 254 is applied to the vicinity of the gathering portion of the first exhaust pipe 241 and the second exhaust pipe 242, the inside of the first and second exhaust pipes 241, 242 Since the exhaust gas can be cooled together and the temperature can be controlled, the efficiency is good.
[0115]
Further, as shown in FIG. 14, the second exhaust pipe 242 is passed through one side portion of the front surface of the V-type engine 100, but the crankcase 104 on the other side portion of the front surface of the V-type engine 100 has the first -Do not let the second exhaust pipes 241 and 242 pass. An oil filter 122, which is a functional component of the engine oil lubrication / cooling system, is added to the crankcase 104 on the other side of the front surface of the V-type engine 100 by effectively using the empty space through which the exhaust pipes 241 and 242 do not pass. Since the oil cooler 123 can be provided, the low floor type vehicle 10 can be downsized.
[0116]
Next, the arrangement configuration of the rear wheel rear cushion 61 will be described.
FIG. 24 is a schematic view of a low-floor type vehicle according to the present invention. A storage box 59 having a front and rear length substantially equal to the front and rear length of the seat 58 is provided below the seat 58, and the rear of the storage box 59 is rearward. It shows that the rear cushion 61 for a wheel is placed horizontally. Referring to FIG. 13, it can be seen that the rear cushion 61 is disposed substantially at the center of the vehicle body (center in the vehicle width direction).
[0117]
25 is a left side view around the storage box and rear wheel rear cushion according to the present invention, and FIG. 26 is a sectional view taken along line 26-26 in FIG.
The rear wheel rear cushion 61 is disposed along the rear portion of the upper frame 22. Specifically, one end of the rear cushion 61 is connected to the cushion bracket 34 of the upper frame 22, and the other end of the rear cushion 61 is connected to the cushion bracket 167 of the swing arm 62. In addition, a rear cushion 61 is disposed substantially parallel to the upper frame 22.
[0118]
The storage box 59 includes an inspection lid 261 for the rear cushion 61 on the bottom surface 59a. The rear cushion 61 includes an adjustment member 61a for adjusting cushioning properties. The bottom surface 59a of the storage box 59 is directly above the adjustment member 61a.
When adjusting the rear cushion 61, the adjustment member 61a may be adjusted by removing the inspection lid 261 that is detachably attached to the bottom surface 59a by elastic engagement and inserting the tool 262 from the inspection hole 59b of the bottom surface 59a. . Adjustment work is easy.
[0119]
The mounting structure of the rear cushion 61 will be described collectively.
Since the rear wheel rear cushion 61 is disposed horizontally below the storage box 59, even if the storage box 59 is extended back and forth, it does not interfere with the rear wheel rear cushion 61 at the approximate center of the vehicle body. Accordingly, a storage box 59 having a front and rear length substantially equal to the front and rear length of the seat 58 can be disposed below the seat 58. For this reason, by enlarging the storage space by increasing the front and back length of the storage box 59, it is possible to easily secure a storage space for storing a long and large-sized object.
[0120]
Further, since the inspection lid 261 for the rear wheel rear cushion 61 is provided on the bottom surface of the storage box 59, the inspection lid 261 can be removed for maintenance and inspection of the rear cushion 61. Maintenance / inspection work can be easily performed without removing the storage box 59 and the vehicle body cover 70 (see FIG. 1), thereby improving workability.
[0121]
Furthermore, since the rear wheel rear cushion 61 is disposed along the rear portion of the upper frame 22 of the diamond-shaped frame 20, the rigidity of the rear wheel rear cushion 61 is sufficiently ensured by the upper frame 22 having high rigidity. And a small suspension structure.
[0122]
FIG. 27 is a modified view of the storage box according to the present invention and corresponds to the embodiment shown in FIG. The storage box 59 of the modified example is characterized in that the inspection lid 263 provided on the bottom surface 59 a has a hinge structure that opens and closes by a hinge 264. About another structure, it is the same as the said FIGS. 24-26, attaches | subjects the same code | symbol and abbreviate | omits the description.
[0123]
Next, a liquid circulation system 270 such as cooling water that circulates in the engine 100 will be described with reference to FIGS.
FIG. 28 is a schematic diagram of a circulation system of liquid circulated through the engine according to the present invention. The liquid circulation system 270 includes, for example, an engine cooling water circulation system 271 that circulates cooling water for cooling the engine 100 itself. And an oil cooler cooling water circulation system 291 that circulates cooling water for cooling the engine oil cooler 123.
[0124]
The engine coolant circulation system 271 includes a delivery line 272 for sending coolant from the engine radiator 55 to the coolant pump 121, a return line 274 for returning coolant from the thermostat valve 273 of the water-cooled engine 100 to the engine radiator 55, and a reserve tank A reserve line 276 from 275 to the engine radiator 55.
The cooling water is supplied from the engine radiator 55 → the delivery line 272 → the cooling water pump 121 → the water cooling jackets (not shown) of the front cylinder 101 and the rear cylinder 102 of the water cooling engine 100 → the thermostat valve 273 → the return line 274 → It circulates along the route of the engine radiator 55.
[0125]
The delivery line 272 is a liquid pipe comprising a delivery pipe 281 having one end connected to the delivery port 55a of the engine radiator 55, and a delivery hose 282 connected from the other end of the delivery pipe 281 to the inlet 121a of the cooling water pump 121. is there.
The return line 274 is a liquid pipe composed of a return pipe 283 having one end connected to the return port 55b of the engine radiator 55, and a return hose 284 connected from the other end of the return pipe 283 to the outlet 273a of the thermostat valve 273. .
[0126]
Reference numerals 277, 278, and 279 denote return hoses. The return hoses 277 and 278 are hoses for returning cooling water from the water cooling jackets (not shown) of the front and rear cylinders 101 and 102 to the thermostat valve 273. The return hose 279 is a hose that returns the cooling water from the thermostat valve 273 to the cooling water pump 121 when the temperature of the cooling water is below a certain level and the thermostat valve 273 is closed.
[0127]
The oil cooler cooling water circulation system 291 branches from the delivery pipe 281 of the delivery line 272, sends a cooling line to the oil cooler 123, a return line 294 that returns the cooling water from the oil cooler 123 to the cooling water pump 121, Consists of.
The cooling water is supplied to each of the water cooling jackets of the engine radiator 55 → the delivery line 272 → the delivery line 293 → the oil cooler 123 → the return line 294 → the cooling water pump 121 → the front cylinder 101 of the water cooling engine 100 and the rear cylinder 102 (see FIG. It circulates in the path | route of the thermostat valve 273-> return line 274-> engine radiator 55.
[0128]
The delivery line 293 is a delivery hose. Return line 294 is a cooling water passage in engine 100.
[0129]
The delivery pipe 281 and the return pipe 283 of the engine coolant circulation system 271 are provided with cooling fins 285 and 286 on the outer surfaces, respectively.
A duct 311 is provided between the front cover 71 (see FIG. 2) and the engine radiator 55. Hereinafter, a detailed configuration of the duct 311 and a detailed configuration of the delivery / return pipes 281 and 283 of the engine coolant circulation system 271 will be described.
[0130]
FIGS. 29A and 29B are configuration examples (part 1) around the front cover and the radiator according to the present invention, and show a first embodiment of the front cover 71 and the duct 311. FIG.
(A) is a front view of the front cover 71, and shows that the two left and right introduction ports 71a and 71a for taking in outside air are opened under the headlamp 83 on the front surface of the front cover 71. Show. (B) is an exploded view showing a structure in which the duct 311 of the first embodiment for guiding the outside air taken in from the inlets 71a and 71a to the radiator 55 is attached to the radiator 55 with screws 312. . The inlets 311 a and 311 a of the duct 311 are matched with the inlets 71 a and 71 a of the front cover 71. Thus, the front cover 71 includes the introduction ports 71a and 71a (311a and 311a) for taking in outside air.
[0131]
FIGS. 30A and 30B are configuration examples (part 2) around the front cover and the radiator according to the present invention, and show a second embodiment of the front cover 71 and the duct 311. FIG.
(A) is the block diagram which looked at the front cover 71 from the front, Comprising: The opening 313a of the duct 313 of 2nd Example is provided in the opening 71b below the headlamp 83 among the front surfaces of the front cover 71. FIG. Indicates placement. (B) is an exploded view showing a structure in which a duct 313 for guiding outside air taken in from the wide inlet 313a to the radiator 55 is attached to the radiator 55 with screws 312. Thus, the front cover 71 includes the introduction port 311a for taking in outside air.
[0132]
FIGS. 31A and 31B are configuration examples (part 3) around the front cover and the radiator according to the present invention, and show a third embodiment of the front cover 71 and the duct 311. FIG.
(A) is a front view of the front cover 71, and two left and right introduction ports 71a and 71a for taking in outside air are opened on the left and right sides of the head lamp 83 on the front surface of the front cover 71. Indicates. (B) is an exploded view showing a configuration in which the duct 314 of the third embodiment for guiding the outside air taken in from the inlets 71a, 71a to the radiator 55 is attached to the radiator 55 with screws 312. . The inlets 314a and 314a of the duct 314 coincide with the inlets 71a and 71a of the front cover 71. Thus, the front cover 71 includes the introduction ports 71a and 71a (314a and 314a) for taking in outside air.
[0133]
FIGS. 32A and 32B are configuration examples (part 4) around the front cover and the radiator according to the present invention, and show a fourth embodiment of the front cover 71 and the duct 311.
(A) is a configuration diagram of the front cover 71 as viewed from the front, and an opening 71b is provided below the headlamp 83 on the front surface of the front cover 71, and outside air is given to the left and right upper corners of the opening 71b. It shows that the two right and left inlets 71a, 71a for opening were opened. (B) is an exploded view showing a structure in which the duct 315 of the fourth embodiment for guiding the outside air taken in from the inlets 71a and 71a to the radiator 55 is attached to the radiator 55 with screws 312. . The inlets 315a and 315a of the duct 315 coincide with the inlets 71a and 71a of the front cover 71. Thus, the front cover 71 includes the inlets 71a and 71a (315a and 315a) for taking in outside air.
[0134]
FIG. 33 is a piping diagram (part 1) of the stay and the engine cooling water circulation system delivery / return pipe according to the present invention viewed from the right side, and FIG. 34 shows the stay and the engine cooling water circulation system delivery / return pipe according to the present invention. Piping diagram (No. 2) viewed from the left side, FIG. 35 is a cross-sectional view of the main part of the front fork and the stay according to the present invention viewed from the front.
[0135]
The stay 320 includes left and right first stays 321 and 321 that are bolted to the head pipe 21, and left and right second stays 322 and 322 that extend forward from the first stays 321 and 321 and support the front cover 71, Left and right third stays 323 and 323 that extend forward and downward from the first stays 321 and 321 to support the radiator 55, and extend rearward from these third stays 323 and 323 via stay plates 324 and 324. The left and right fourth stays 281 and 283 are bolted to the down frame 23 of the vehicle body frame 20.
[0136]
In the present invention, the right fourth stay 281 is constituted by a pipe as shown in FIG. 33, and this pipe is used as a delivery pipe 281. The left fourth stay 283 is constituted by a pipe as shown in FIG. However, this pipe is a return pipe 283.
[0137]
The delivery pipe 281 and the return pipe 283 of the engine cooling water circulation system 271 are pipes that are separately passed through the left and right sides of the front fork 51, and the cooling fins 285 and 286 are placed along the outer surfaces of these pipes 281 and 283, respectively. It is provided. These cooling fins 285 and 286 are plate members facing up and down, and are members that are brought into close contact with the outer surfaces of the pipes 281 and 283 and fixed by welding or the like. In addition to steel pipes or the like, a material having excellent thermal conductivity ( For example, an aluminum alloy may be used.
[0138]
When the low-floor vehicle 10 is driven, the traveling wind taken from the inlet 71a of the front cover 71 flows along the path of the inlet 311a → the duct 311 → the radiator 55 to cool the cooling water, and further flows backward. After cooling the pipes 281 and 283 and the cooling fins 285 and 286, they flow toward the rear of the vehicle body. In this way, the cooling water flowing in the pipes 281 and 283 can be cooled with the outside air.
[0139]
FIG. 36 is a piping diagram of the stay and the engine cooling water circulation system delivery / return pipe (modified example) as viewed from the right side, and FIG. 37 is a front fork and stay (modified example) of the present invention as viewed from the front. FIG.
[0140]
The stay 320 of the modified example passes two fourth stays 281, 283, that is, the delivery pipe 281 and the return pipe 283, concentrated on the left and right sides of the front fork 51, and passes through the outer surfaces of the delivery / return pipes 281, 283. A feature is that cooling fins 287 are provided along. Other configurations are the same as the configurations shown in FIGS. 33 to 35, and the same reference numerals are given, and the description thereof is omitted.
[0141]
In FIG. 36, the cooling fins 287 for cooling the delivery / return pipes 281 and 283 are integrally formed, but a cooling fin for cooling the delivery pipe 281 and a cooling fin for cooling the return pipe 283 are provided separately. May be.
Of the stay 320 of this modification, the left and right other side of the front fork 51 has a general stay structure using pipe material, bar material, etc. as shown in FIG.
[0142]
The above circulation system 270, stay 320, front cover 71, and duct 311 will be described together.
Of the stay 320 that supports the front cover 71, at least a part 281, 283 is constituted by a pipe, and this pipe is a part of the liquid piping (sending / returning pipes 281, 283), thereby circulating to the engine 100. Cooling water or other liquid can be passed through the pipe. Since the stay 320 also serves as a part of the liquid piping, piping parts can be reduced, so that the piping cost can be reduced. Furthermore, as the stay 320 also serves as a part of the liquid piping, the stay 320 and the liquid piping are alleviated from being concentrated in the front cover 71, and the weight can be reduced. Therefore, the degree of freedom in design around the front cover 71 is increased, and the low-floor type vehicle 10 (motorcycle 10) can be reduced in size and weight, and the degree of freedom in design can be increased.
[0143]
For example, when the engine 100 is disposed on the vehicle body frame 20 and the radiator 55 is disposed in front of the head pipe 21, the pipe (engine cooling water circulation system 271) connecting the engine 100 and the radiator 55 is located near the head pipe 21. Pass through. In the vicinity of the head pipe 21, a stay 320 for supporting the front cover 71 covering the front portion of the head pipe 21 on the vehicle body frame 20 is also passed. Such a stay 320 can be used for a part of the liquid piping.
[0144]
Furthermore, since the front cover 71 is provided with the introduction port 71a (311a) that can take in outside air and flow it around the pipes 281 and 283, the liquid flowing in the pipes 281 and 283 can be cooled with outside air. . Since the liquid passing through the pipes 281 and 283 is cooled, the cooling effect is enhanced. For example, when the cooling water of the engine 100 is circulated and cooled by the radiator 55, the cooling capacity of the radiator 55 can be reduced by the amount of cooling effect of the pipes 281 and 283. As a result, the radiator 55 can be reduced in size.
[0145]
Furthermore, since the cooling fins 285, 286, and 287 are provided on the outer surfaces of the pipes 281 and 283, the cooling efficiency for cooling the liquid flowing in the pipes 281 and 283 with the outside air can be further increased. Further, the cooling fins 285, 286, and 287 can also function as reinforcing members for the pipes 281 and 283.
[0146]
Next, modified examples of the liquid circulation system 270 will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected about the structure similar to the structure shown to the said FIG. 28-FIG. 37, and the description is abbreviate | omitted.
[0147]
FIG. 38 is a schematic diagram of a circulation system (modified example) of liquid circulated through the engine according to the present invention. The circulation system 270A of this modified example is configured to completely connect the engine cooling water circulation system 271 and the oil cooler cooling water circulation system 291A. It is characterized by being separated or almost separated.
Specifically, the liquid circulation system 270A includes, for example, an engine cooling water circulation system 271 that circulates cooling water for cooling the engine 100 itself, and an oil that circulates cooling water for cooling the engine oil cooler 123. It consists of a cooler cooling water circulation system 291A.
The engine coolant circulation system 271 is the same as the circulation system 271 shown in FIG.
[0148]
The oil cooler cooling water circulation system 291A includes a delivery line 293A for sending cooling water from the oil cooler radiator 292A to the oil cooler 123, a return line 294 for returning cooling water from the oil cooler 123 to the cooling water pump 121, and an oil from the thermostat valve 273A. And a return line 295A for returning the cooling water to the cooler radiator 292A.
The thermostat valve 273A of the modified example includes two cooling water outlets (outlets 273a and 273b).
[0149]
The cooling water is an oil cooler radiator 292A → a discharge line 293A → an oil cooler 123 → a return line 294 → a cooling water pump 121 → a water cooling jacket (not shown) for each of the front cylinder 101 and the rear cylinder 102 of the water cooling engine 100. It circulates through the path of the thermostat valve 273A, the return line 295A, and the oil cooler radiator 292A.
[0150]
The delivery line 293A is a liquid pipe comprising a delivery pipe 301 having one end connected to the delivery port 292a of the oil cooler radiator 292A, and a delivery hose 302 connected from the other end of the delivery pipe 301 to the inlet 123a of the oil cooler 123. is there.
The return line 295A is a liquid pipe composed of a return pipe 303 having one end connected to the return port 292b of the radiator 292A for the oil cooler and a return hose 304 connected from the other end of the return pipe 303 to the outlet 273b of the thermostat valve 273A. is there.
[0151]
The delivery pipe 301 and the return pipe 303 of the oil cooler cooling water circulation system 291A are provided with cooling fins 305 and 306 on the outer surfaces, respectively.
A duct 311 is provided between the front cover 71 (see FIG. 2) and each of the radiators 55 and 292A.
[0152]
Hereinafter, detailed configurations of the delivery / return pipes 281 and 283 of the engine coolant circulation system 271 and the delivery / return pipes 301 and 303 of the oil cooler coolant circulation system 291A will be described with reference to FIGS. 39 and 40.
39 shows an example in which the cooling fins 285 and 305 of FIG. 38 are integrated, and FIG. 40 shows an example of the cooling fins 308 in which the cooling fins 286 and 306 are also integrated. However, these cooling fins 285, 286, 305, and 306 may be provided separately.
[0153]
39 is a piping diagram (part 1) of the stay and the engine cooling water circulation system delivery / return pipe (modified example) as seen from the right side according to the present invention, and FIG. 40 is the stay and engine cooling water circulation system delivery according to the present invention. -It is the piping figure (the 2) which looked at the return pipe (modification) from the left side.
[0154]
The modified stay 320 has the following configurations (1) and (2).
(1) As shown in FIG. 39, the two fourth stays 281, 301, that is, the delivery pipes 281, 301 are concentrated on the left and right sides of the front fork 51 and passed through the outer surface of the delivery pipes 281, 301. The structure which provided the cooling fin 307 along.
(2) As shown in FIG. 40, the two fourth stays 283 and 303, that is, the return pipes 283 and 303, are concentrated on the left and right sides of the front fork 51 and passed through the outer surface of the return pipes 283 and 303. A configuration in which cooling fins 308 are provided.
[0155]
In the embodiment, the cooling water pump 121 and the thermostat valve 273A share one, but they are provided separately to completely connect the engine cooling water circulation system 271 and the oil cooler cooling water circulation system 291A. It may be separated and independent.
As described above, by completely separating the engine coolant circulation system 271 and the oil cooler coolant circulation system 291A, it becomes easy to make the temperatures of the coolant circulation systems 271, 291A appropriate.
Further, for the liquid circulation systems 270 and 270A, this structure can be applied to an oil cooler of an air-cooled engine.
[0156]
Next, a modification of the cleaner case 201 of the air cleaner 56 shown in FIG. 18, that is, the engine intake chamber 201 will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected about the structure similar to each structure shown to the said FIGS. 1-24, and the description is abbreviate | omitted.
[0157]
41 is a left side view of a low-floor vehicle equipped with an engine intake chamber (first modification) according to the present invention, and FIG. 42 is a plan view of the engine intake chamber (first modification) according to the present invention. FIG. 43 is a front view of an engine intake chamber (first modification) according to the present invention.
[0158]
The engine intake chamber 331 of the first modification includes a pair of left and right first intake chambers 332 and 332 disposed on the left and right sides of the front wheel 52. Specifically, the left and right first intake chambers 332 and 332 are disposed on both the left and right sides of the front wheel 52 and at the rear upper part of the front wheel 52, and in the cover extensions 333 and 333 that extend downward in the left and right rear portions of the front cover 71. It is arranged in. Therefore, the first intake chambers 332 and 332 are elongated members extending rearward and downward along the cover extension portions 333 and 333 when viewed from the side, and the intake pipes 334 and 334 extending forward from the front upper end. Have
[0159]
Furthermore, the first intake chambers 332 and 332 are formed by forming upper surfaces 332a and 332a inclined rearward and downward on a substantially flat surface so as to also serve as a part of a footrest portion on which a driver's foot is placed. The first intake chambers 332 and 332 may be arranged so that the upper surfaces 332a and 332a extend forward and upward from the front ends of the left and right low floors 73 and 73 on which the driver's feet are placed. In this way, the driver can arbitrarily put his / her feet on the low floors 73 and 73 and the upper surfaces 332a and 332a.
[0160]
In the first modified example, a second intake chamber 335 on the downstream side connected to the first intake chambers 332 and 332 is disposed on the first intake chambers 332 and 332 and at the center of the vehicle width (vehicle center) CL. In addition, engine auxiliary parts such as a fuel tank 57 (see FIG. 41) are arranged above the second intake chamber 335.
Accordingly, the intake system 190 according to the first modification connects the downstream side second intake chamber 335 to the upstream side first intake chambers 332 and 332 via the substantially inverted Y-shaped chamber connection pipe 336 when viewed from the front. Further, the cylinders 101 and 102 of the V-type engine 100 are connected to the second intake chamber 335 via intake connection pipes 191 and 191.
[0161]
FIG. 44 is a left side view of a low floor vehicle equipped with an engine intake chamber (second modification) according to the present invention.
The intake system 190 of the second modification has a large pair of left and right first intake chambers 332 and 332 arranged on the left and right sides of the front wheel 52, and a first arrangement disposed on the first intake chambers 332 and 332. By reducing the thickness of the second intake chamber 335, the total capacity is ensured. The height of the second intake chamber 335 is reduced by the thickness of the second intake chamber 335. For this reason, since a larger empty space can be provided above the second intake chamber 335, engine auxiliary parts such as the fuel tank 57 having a large tank capacity can be easily arranged.
[0162]
The above intake system 190 will be described together.
Since the engine intake chamber 331 is disposed by effectively utilizing at least one of the empty spaces that have not been used in the side of the front wheel 52 in the low floor type vehicle 10, a large-capacity intake chamber is provided. A sufficient space for arranging 331 can be secured. Since the capacity of the intake chamber 331 can be increased, the performance of the engine 100 can be sufficiently exhibited. Therefore, the low-floor type vehicle 10 can be made a vehicle that is easier to ride and has high traveling performance. In addition, since a large-capacity intake chamber can be employed, noise due to air vibration in the intake chamber 331 can be reduced.
[0163]
Furthermore, since a large space for arranging the intake chamber 331 can be secured, the degree of freedom in designing the intake system 190 is increased. Furthermore, the center of gravity of the low floor vehicle 10 can be lowered by disposing the engine intake chamber 331 on the side of the front wheel 52. Therefore, the maneuverability of the low floor type vehicle 10 is further enhanced.
[0164]
Furthermore, since the engine intake chamber 331 is composed of a pair of left and right first intake chambers 332 and 332 disposed on the left and right sides of the front wheel 52, the left and right empty spaces on the left and right sides of the front wheel 52 have large capacity. A pair of first intake chambers 332 and 332 can be disposed. The total capacity of the engine intake chamber 331 can be further increased.
Further, since the second intake chamber 335 on the downstream side connected to the first intake chambers 332 and 332 is further disposed on the left and right first intake chambers 332 and 332 having a large capacity, the intake air for the engine The total capacity of the chamber 331 can be significantly increased.
[0165]
By the way, conventionally, an intake chamber is often arranged in a space above the V-type engine 100, and thus there is a limitation in arranging other parts in such a space.
On the other hand, the engine 100 of the present invention is a V-type engine that has V-type cylinders 101 and 102 and is arranged in the center of the vehicle body. By disposing the engine intake chamber 331 on the side of the front wheel 52, such a point could be solved. That is, the space above the V-type engine 100 can be afforded, and engine auxiliary parts such as the fuel tank 57 can be arranged in this space.
[0166]
Further, since the pair of left and right first intake chambers 332 and 332 are disposed on both the left and right sides of the front wheel 52, the second intake chamber 335 can be disposed at a low level. Therefore, engine auxiliary parts such as the fuel tank 57 can be easily arranged above the low second intake chamber 335.
[0167]
Furthermore, since the pair of left and right first intake chambers 332 and 332 also serve as a part of the footrest portion, the number of parts of the footrest portion can be reduced. As a result, it is possible to reduce the weight of the low floor type vehicle 10 and to reduce the cost. Further, by driving with the feet placed on the pair of left and right first intake chambers 332 and 332, the pulsation of the air in the left and right first intake chambers 332 and 332 is caused by the feet through the walls of the chambers 332 and 332. You can feel it directly. In this way, it is possible to experience the pulsation (beat) of the power system while reducing noise caused by air vibration in the first and second intake chambers 331 and 335.
[0168]
Next, the relationship between the low floor 73 and the engine 100 will be described with reference to FIG. 45 (a) and 45 (b) are configuration diagrams around the low floor according to the present invention, (a) is a perspective view around the left low floor 73, and (b) is a cross-sectional view taken along the line bb of (a). It is sectional drawing which looked at the figure, ie, the surroundings of the left low floor 73 from the left side.
In this figure, in a low-floor type vehicle 10 such as a scooter-type motorcycle or tricycle in which an engine 100 is disposed below the low floor 73, a notch 73a is opened in a part of the low floor 73, and the engine is provided in the notch 73a. It is shown that a part of the exposed engine 100 is configured to also serve as a footrest portion on which the driver's foot is placed by facing a part of the engine 100.
[0169]
The part of the engine 100 facing the notch 73a is, for example, the cover 118 that covers the AC generator 116 (see FIG. 11) attached to the engine 100, that is, the left side cover 118. The left side cover 118 has an upper surface 118a which is a flat flat portion 118a, an inspection opening 118b provided in the flat portion 118a, and the inspection opening 118b is closed by a removable lid 341. is there. The present invention is characterized in that the flat portion 118a of the left side cover 118 is a substantially horizontal surface along the floor surface (upper surface) 73b of the low floor 73 and is set at substantially the same level as the low floor 73. .
[0170]
A notch 73a is opened in a part of the low floor 73, and a part of the engine 100 (that is, the upper part of the left side cover 118) faces the notch 73a. There is no need to provide a gap between them. Accordingly, the height of the low floor 73 can be lowered. In addition, since a part of the engine 100 facing the notch 73a of the low floor 73 is also used as a footrest portion on which the driver's feet are placed, a sufficient footrest area can be secured. Because of this, there is room in the driver's feet. Therefore, the driver's fatigue can be further reduced. Furthermore, not only the driver's footrest portion but also the passenger's footrest portion can be provided on the low floor 73 by extending the footrest portion rearward.
[0171]
Furthermore, the height of the low floor 73 can be lowered by a light and simple configuration. In addition, although the height of the low floor 73 is lowered, it is possible to increase the height of the engine 100, thereby improving the maintenance and inspection workability of the engine 100.
[0172]
In addition, since a part of the engine 100 facing the notch 73a is a flat flat portion at substantially the same level as the low floor 73, a part of the engine 100 facing the notch 73a is As a part of the footrest portion, it can function more effectively. The driver can freely put his / her legs on the low floor 73 and the engine 100 facing the notch 73a. Therefore, the driver's fatigue can be further reduced.
[0173]
Further, since a part of the engine 100 is configured by the left side cover 118 that covers the AC generator 116 attached to the engine 100, the maintenance / inspection of the AC generator 116 is performed by removing a part of the left side cover 118. Work can be done easily.
[0174]
In addition, since the inspection opening 118b is provided on the upper surface 118a of the left side cover 118, and the inspection opening 118b is closed with a removable lid 341, the lid 341 is opened and the inspection opening 118b is opened. Maintenance and inspection work of the AC generator 116 can be performed more easily.
[0175]
Further, the floor mat 343 that covers at least the notch 73a is disposed on the floor surface (upper surface) 73b of the low floor 73, so that the notch 73a is covered with the floor mat 343, and therefore the engine 100 facing the notch 73a. A part (that is, the upper part of the left side cover 118) of the dustproof effect can be enhanced, and the appearance of the low floor vehicle 10 can be enhanced.
[0176]
In the above-described embodiment of the present invention, the low floor type vehicle 10 is not limited to a scooter type motorcycle, but may be another motorcycle, a three-wheeled vehicle, a four-wheeled vehicle, or the like.
[0177]
【The invention's effect】
  The present invention exhibits the following effects by the above configuration.
  Claim 1 is a low-floor type vehicle such as a scooter type motorcycle or tricycle, wherein a storage space is provided under the seat, and left and right low floors on which a driver sitting on the seat puts his / her foot in front of the seat In a low-floor type vehicle in which a driver is provided between the right and left low floors, and a straddle with a height that can be straddled by a driver is provided, and an engine is provided under the straddle.The low-floor type vehicle includes a diamond-shaped frame including a pair of left and right upper frames extending downward from the head pipe and a down frame extending downward from the head pipe. A V-type engineThe engine is a V-type engine having a front cylinder and a rear cylinder, and a crankshaft is disposed under the straddle portion,RearThe cylinder axis is directed upward, and the top of the cylinder faces the straddle,A fuel tank is provided in front of the straddle, above the air cleaner connected to the engine and above the upper frame.It is characterized by that.
  In low-floor vehicles such as scooter type motorcycles and tricycles, the engine crankshaft is placed under the straddle and the engineRearSince the top of the cylinder faces the straddle, a large space can be secured in front of the engine.
  By effectively utilizing this space and arranging the intake system including the intake connection pipe and the air cleaner, the intake connection pipe can have a relatively simple shape close to a straight line. Therefore, the intake system and the V-type engine can be efficiently connected, and the performance of the engine can be improved. Furthermore, the degree of freedom in designing the intake system is increased.
  Furthermore, by disposing the air cleaner at a relatively low position in front of the engine, it is possible to secure a relatively low additional space above the air cleaner. By effectively utilizing this additional space, functional parts such as a fuel tank can be easily arranged.
  Further, since the two cylinders of the V-type engine are arranged in the front-rear direction, the vehicle width does not have to be widened, and the running performance can be improved.
[0178]
  In claim 1,The fuel tank in front of the straddle, EnAbove the air cleaner connected to the gin, andA pair of left and right sides extending downward from the head pipeProvided above the upper frameSoBy placing a fuel tank in front of the straddle, it is not necessary to place a fuel tank below the seat, so a large space is secured under the seat and the storage capacity of the storage box is greatly increased (increasing capacity) And the degree of freedom in designing the storage box can be increased.
  In addition, the air cleaner is disposed at a relatively low position, and the fuel tank can be easily disposed in a space secured above the air cleaner, so that the space can be effectively used.
[0179]
  Furthermore, in claim 1,The low-floor type vehicle includes a diamond-shaped frame including a pair of left and right upper frames extending rearward and downward from the head pipe and a down frame extending rearward and downward from the head pipe. To suspend the engineSoDiamond frame with engine connected to down frameAndThe engine can be easily lowered to the minimum ground level. Therefore, the center of gravity of the low floor vehicle can be easily lowered.
  Claim 2 is the method of claim 1,The bank angle of the V-type engine is set to 90 ° or an angle exceeding 90 °, and the bisector of this bank angle is set toThe head pipeIt is characterized by being directed to.
  In claim 2,By setting the bank angle to 90 ° or an angle exceeding 90 °, a large space is provided between the V banks, and an intake system including an intake connecting pipe and an air cleaner is disposed in the space. Can be efficiently connected, and engine performance can be improved.
  Also, since the bisector of the bank angle is directed to the head pipe and the V-type engine is arranged, the bisector is oriented in the direction where the vehicle body rigidity is strong. Can be advantageous.
  Claim 3 is the method of claim 1,The bottom surface of the substantially planar air cleaner to which the intake connection pipe is connected is substantially orthogonal to the bisector of the bank angle, and the upper frame and the down frame are substantially straight from the bottom surface of the air cleaner to the vicinity of each cylinder. It is made to form in.
  In claim 3,Since the space inside the body frame can be effectively used and arranged compactly, the degree of freedom in design can be increased, and the appearance of the low-floor type vehicle can be improved. Furthermore, the ease of straddling the body frame can be improved when the driver gets on.
  Claim 4 is the method of claim 1,SaidRear cylinderIs disposed between the left and right upper frames, and the front end of the cylinder at the rear is substantially coincident with the contour line on the upper side of the upper frame.
  In claim 4, the rearSince the cylinder is disposed between the left and right upper frames, even if the upper frame is lowered, it does not interfere with the cylinders in the rear bank.
  For this reason, it is possible to pass the upper frame as low as possible. Accordingly, the center of gravity of the vehicle body frame is lowered, so that the center of gravity of the low floor type vehicle can be lowered. In addition, since the low floor can be made lower, the comfortability and footing of the low floor vehicle are improved. Furthermore, lowering the upper frame makes it easier to straddle the body frame when the driver gets on.
[Brief description of the drawings]
FIG. 1 is a left side view of a low floor type vehicle according to the present invention (part 1).
FIG. 2 is a left side view of a low floor type vehicle according to the present invention (part 2).
FIG. 3 is a plan view of a low floor vehicle according to the present invention.
FIG. 4 is a left side view of a vehicle body frame according to the present invention.
FIG. 5 is a plan view of a vehicle body frame according to the present invention.
FIG. 6 is a front view of a vehicle body frame according to the present invention.
7 is a perspective view of the vehicle body frame according to the present invention as viewed from the left side. FIG.
FIG. 8 is a perspective view of a vehicle body frame according to the present invention as viewed from the right side.
FIG. 9 is a left side view around the vehicle body frame, power unit, air cleaner and fuel tank according to the present invention.
FIG. 10 is a cross-sectional view of a power unit according to the present invention.
FIG. 11 is a cross-sectional view of the front half of the power unit according to the present invention.
FIG. 12 is a cross-sectional view of the latter half of the power unit according to the present invention.
FIG. 13 is a plan view of the rear portion of the power unit according to the present invention and the periphery of the swing arm for the rear wheel.
FIG. 14 is a perspective view of the body frame and the power unit according to the present invention as viewed from the left front.
FIG. 15 is a perspective view of the vehicle body frame, power unit, and air cleaner according to the present invention as viewed from the left rear.
FIG. 16 is a perspective view of the vehicle body frame, the power unit, and the air cleaner according to the present invention as viewed from the right front side.
FIG. 17 is a perspective view of the body frame and the power unit according to the present invention viewed from the right rear side.
FIG. 18 is a left side view around a vehicle body frame, a V-type engine, and an intake system according to the present invention.
FIG. 19 is a rear sectional view around the air cleaner and the vehicle body cover according to the present invention.
FIG. 20 is an exploded view of an air cleaner according to the present invention.
FIG. 21 is an operation diagram of an air cleaner according to the present invention.
FIG. 22 is a left side view around the vehicle body frame, power unit, and exhaust system according to the present invention.
FIG. 23 is a plan view around the vehicle body frame, power unit, and exhaust system according to the present invention.
FIG. 24 is a schematic view of a low floor vehicle according to the present invention.
FIG. 25 is a left side view around the storage box and rear wheel rear cushion according to the present invention.
26 is a cross-sectional view taken along the line 26-26 in FIG.
FIG. 27 is a modified view of a storage box according to the present invention.
FIG. 28 is a schematic diagram of a circulation system for liquid circulating in the engine according to the present invention.
FIG. 29 is a diagram showing a configuration example around a front cover and a radiator according to the present invention (part 1).
FIG. 30 is a diagram of a configuration example around the front cover and the radiator according to the present invention (part 2).
FIG. 31 is a structural example (part 3) around the front cover and the radiator according to the present invention.
FIG. 32 is a diagram showing a configuration example around the front cover and the radiator according to the present invention (part 4);
FIG. 33 is a piping diagram of a stay and an engine cooling water circulation system sending / return pipe according to the present invention viewed from the right side (part 1).
FIG. 34 is a piping diagram (part 2) of the stay 320 according to the present invention and the delivery / return pipe of the engine coolant circulation system as viewed from the left side.
FIG. 35 is a cross-sectional view of the main part of the front fork and stay according to the present invention as seen from the front.
FIG. 36 is a piping diagram of the stay and the engine cooling water circulation system delivery / return pipe (modified example) as seen from the right side according to the present invention.
FIG. 37 is a cross-sectional view of the main part of the front fork and stay (modification) according to the present invention as seen from the front.
FIG. 38 is a schematic diagram of a circulation system (modified example) of liquid circulating in the engine according to the present invention.
FIG. 39 is a piping diagram (No. 1) of the stay and the engine cooling water circulation system delivery / return pipe (modified example) as seen from the right side according to the present invention;
FIG. 40 is a piping diagram (part 2) of the stay and the engine cooling water circulation system delivery / return pipe (modified example) as seen from the left side according to the present invention.
FIG. 41 is a left side view of a low floor vehicle equipped with an engine intake chamber (first modification) according to the present invention.
FIG. 42 is a plan view of an engine intake chamber (first modification) according to the present invention.
FIG. 43 is a front view of an engine intake chamber (first modification) according to the present invention;
FIG. 44 is a left side view of a low floor vehicle equipped with an engine intake chamber (second modification) according to the present invention.
FIG. 45 is a configuration diagram around a low floor according to the present invention.
[Explanation of symbols]
  10 ... Low floor type vehicle,21 ... head pipe, 22 ... upper frame, 23 ... down frame, 56 ... air cleaner,57 ... Fuel tank, 58 ... Seat, 59 ... Storage space (storage box), 73 ... Low floor, 78 ... Crossing part, 100 ... V-type engine, 101 ... Front cylinder, 102 ... Rear cylinder, 103 ... Crank axis,191: Intake connecting pipe, θ1: Bank angle, L1: Bisecting line.

Claims (4)

A low-floor type vehicle such as a scooter type motorcycle or tricycle, provided with a storage space under the seat, and in front of the seat, left and right low floors on which the driver sits on the seat, In the low floor type vehicle in which a driver has a straddle height that can be straddled between the low floors, and an engine is provided under the straddle,
The low-floor type vehicle includes a diamond-shaped frame including a pair of left and right upper frames that extend rearward and downward from the head pipe, and a down frame that extends downward from the head pipe. Suspended type engine,
The V-type engine is a V-type engine having a front cylinder and a rear cylinder, with placing the crankshaft below the straddle portion, the axis of the rear cylinder is oriented upward, the top Facing the straddle,
A fuel tank is provided in front of the straddle, above the air cleaner connected to the engine and above the upper frame.
A low-floor type vehicle characterized by that. The low floor type according to claim 1 , wherein the bank angle of the V-type engine is set to 90 ° or an angle exceeding 90 °, and a bisector of the bank angle is directed to the head pipe. vehicle.   The bottom surface of the substantially planar air cleaner to which the intake connection pipe is connected is substantially perpendicular to the bisector of the bank angle, and the upper frame and the down frame are substantially straight from the bottom surface of the air cleaner to the vicinity of each cylinder. The low floor type vehicle according to claim 1, wherein the low floor type vehicle is formed. Wherein the rear portion of the cylinder is disposed between the left and right upper frames, the low floor type vehicle according to claim 1, wherein the cylinder tip of the rear portion, characterized in that roughly match the contour of the upper upper frame.

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